José Trinidad Álvarez Romero, Gonzalo Walwyn Salas, María de Los Angeles Montes Rodríguez, Mario Raymundo Cabrera Vertti, Andy Luis Romero Acosta
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引用次数: 0
摘要
本工作介绍了墨西哥国家核研究所二级标准剂量测定实验室(SSDL-ININ)与试点实验室古巴放射保护与健康中心(SSDL-CPHR)之间的双边比较结果,以实现空气开尔玛(${\boldsymbol{K}}_{\boldsymbol{a}}$)量:(i) 诊断 X 射线 (DXR) IEC 61267:2005 光束质量:(ii) 辐射防护 (RP) ISO 4037:2019 X 射线束质量:N60、N100 和 W60,以及伽马辐射的 S-Cs。在 SSDL-ININ 使用东芝 E7252FX X 射线管实现了匹配和特征参考场。在所有情况下,${бoldsymbol{K}}_{\бoldsymbol{a}}$ 的测量都可追溯到 PTB,但 S-Cs 除外,可追溯到 ININ。SSDL-CPHR 还通过 Pantak HF160C X 射线管实现了匹配参考场的参考辐射光束质量。在 S-Cs 光束质量方面,CPHR 使用布赫勒 OB6 辐照器;ININ 使用西门子 Cesagammatron。校准 RQR 和 RQT 质量的转移电离室是 Exradin A650/DO70312;校准 CT 的 RQT 质量的是 PTW 30009/0655 和 RC3CT/9217;校准 RP X 射线质量的是 Exradin A650/DO70312 和 PTW 32002/073。RQR 质量的每个 SSDL 的校准系数${\boldsymbol{N}}_{\{boldsymbol{K}}_{boldsymbol{a}}$ 的比值在$\boldsymbol{U}}\left(\boldsymbol{k}=\mathbf{2}\right)\$ ≤ 2.3%;对于 RQT 质量,差异小于 $\boldsymbol{U}left(\boldsymbol{k}=\mathbf{2}\right)\%$ ≤ 3.6%;对于 RP X 射线质量,差异在 $\boldsymbol{U}left(\boldsymbol{k}=\mathbf{2}\right)\%$ ≤ 3.5% 的范围内。就 S-Cs 质量而言,${\boldsymbol{R}}_{\boldsymbol{k}}$ 在$\boldsymbol{U}left(\boldsymbol{k}=\mathbf{2}\right)$ ≤ 3.0% 的范围内。需要注意的是,由于 ${\boldsymbol{k}}_{\boldsymbol{TP}}$ 修正系数的失效,ININ U 的值通常较大,在此进行简要讨论。ISO 17043 中的 ${boldsymbol{E}}_{\boldsymbol{n}}$ 分数为这种比较提供了统计支持。
Results of the proficiency test for the Ka CMC of the SSDL-ININ Mexico, for diagnostic radiology IEC 61267:2005 and radiation protection ISO 4037:2019 X-ray beam qualities.
The present work describes the results for the bilateral comparison between the Secondary Standards Dosimetry Laboratories of the Instituto Nacional de Investigaciones Nucleares (SSDL-ININ), Mexico, and the pilot laboratory, the Centro de Protección e Higiene de las Radiaciones (SSDL-CPHR), Cuba, for the realization of the air kerma (${\boldsymbol{K}}_{\boldsymbol{a}}$) quantity to: (i) diagnostic X-ray (DXR) IEC 61267:2005 beam qualities: RQR 5 RQR 9, RQT 8, and RQT 9 and (ii) radiation protection (RP) ISO 4037:2019 X-ray beam qualities: N60, N100, and W60, as well S-Cs for gamma radiation. The matched and characterized reference fields are realized at SSDL-ININ with a Toshiba E7252FX X-ray tube. In all cases, the ${\boldsymbol{K}}_{\boldsymbol{a}}$ measurements are traceable to PTB, except for S-Cs, traceable to ININ. The SSDL-CPHR realizes its reference radiation beam qualities also as matched reference fields with a Pantak HF160C X-ray tube. For the S-Cs beam quality, the CPHR uses a Buchler OB6 irradiator; the ININ, a Siemens Cesagammatron. The transfer ionization chambers calibrated in the RQR and RQT qualities are an Exradin A650/DO70312; for the RQT qualities for CT, a PTW 30009/0655 and RC3CT/9217 were calibrated; and for the RP X-ray qualities, the Exradin A650/DO70312 and a PTW 32002/073 were calibrated. The ratio ${\boldsymbol{R}}_{\boldsymbol{k}}$ of the resulting calibration coefficients ${\boldsymbol{N}}_{{\boldsymbol{K}}_{\boldsymbol{a}}}$ of each SSDL of the RQR qualities are consistent within the $\boldsymbol{U}\left(\boldsymbol{k}=\mathbf{2}\right)\%$ ≤ 2.3%; for the RQT qualities, the differences are less than the $\boldsymbol{U}\left(\boldsymbol{k}=\mathbf{2}\right)\%$ ≤ 3.6%; and for the RP X-ray qualities, within the order of $\boldsymbol{U}\left(\boldsymbol{k}=\mathbf{2}\right)\%$ ≤ 3.5%. For the S-Cs quality, the ${\boldsymbol{R}}_{\boldsymbol{k}}$ is in the order of $\boldsymbol{U}\left(\boldsymbol{k}=\mathbf{2}\right)$ ≤ 3.0%. It should be noted that the ININ U's are generally larger due to the failure of the ${\boldsymbol{k}}_{\boldsymbol{TP}}$ correction factor, a brief discussion is given here. The ${\boldsymbol{E}}_{\boldsymbol{n}}$ score from ISO 17043 provides statistical support to this comparison.
期刊介绍:
Radiation Protection Dosimetry covers all aspects of personal and environmental dosimetry and monitoring, for both ionising and non-ionising radiations. This includes biological aspects, physical concepts, biophysical dosimetry, external and internal personal dosimetry and monitoring, environmental and workplace monitoring, accident dosimetry, and dosimetry related to the protection of patients. Particular emphasis is placed on papers covering the fundamentals of dosimetry; units, radiation quantities and conversion factors. Papers covering archaeological dating are included only if the fundamental measurement method or technique, such as thermoluminescence, has direct application to personal dosimetry measurements. Papers covering the dosimetric aspects of radon or other naturally occurring radioactive materials and low level radiation are included. Animal experiments and ecological sample measurements are not included unless there is a significant relevant content reason.